Simulation Of String Breaking Built With Quantum Computing

Scientists improved particle physics simulation by utilising quantum computers to simulate and watch “string breaking” in real time. Traditional computers couldn't replicate this complicated process, in which subatomic particles like quarks are joined by "strings" of force fields that release energy when they break.

The groundbreaking findings are the latest step towards using quantum computers for simulations that surpass conventional machines. These quantum simulations are “incredibly encouraging,” says LBNL scientist Christian Bauer. He said “string breaking is a very important process that is not yet fully understood from first principles”. Classical computers can calculate the ultimate effects of particle collisions involving string generation or breaking, but not the intermediate dynamics.

Two Simulation Methods Revealed

Two worldwide academic-business research teams conducted the experiments. Two teams worked at theGoogle Quantum AI Lab in Santa Barbara, California, and Cambridge startup QuEra Computing. These groups discovered string breaking employing “diametrically opposite quantum-simulation philosophies”:

Analogue Quantum Simulation (QuEra Computing):

This team included Harvard, Innsbruck, and QuEra Computing researchers using QuEra's Aquila computer.

The data was encoded in rubidium atoms kept in place by optical “tweezers” in a 2D honeycomb or kagome-geometry pattern.

The electric field at a given position in space was reflected by each atom's qubit, which could be stimulated or relaxed.

This analogue quantum simulation relied on arranging the atoms so that their electrostatic forces mimicked the electric field. This arrangement allowed the system to continuously attain lower energy levels.

This technology allowed the first observation of string breaking in a programmable two-dimensional quantum simulator. The “tabletop analogue of quark confinement,” a key property of QCD, was achieved.

◦ Daniel González-Cuadra, co-author of the QuEra paper and theoretical physicist and assistant professor at the Institute for Theoretical Physics (IFT) in Madrid, said neutral-atom devices can now solve theoretical difficulties. He said “seeing string breaking in a controlled 2D environment marks a critical step towards using quantum simulators to explore high-energy physics”.

Alexei Bylinskii, QuEra's VP of Quantum Computing Services, said this alliance “underscores the value of open, programmable neutral-atom hardware for fundamental research.” Research in condensed-matter, high-energy, and quantum-information science is enhanced by flexible access to Aquila's multi-qubit capabilities.

Professor Peter Zoller, a senior author at IQOQI and the University of Innsbruck and “founding father of modern quantum simulation,” said “Gauge theories govern much of modern physics.” By showing non-abelian gauge fields and topological matter in two dimensions where strings can bend and fluctuate, the basis is established for studying them.

The experiment featured dynamic quenches using local detuning ‘kicks’ to watch strings snap and re-form in real time, revealing resonance peaks signalling many-body tunnelling processes; programmable geometry, where atoms were placed on hexagonal lattice links to enforce Gauss's-law constraints via Rydberg blockade; and tuneable string tension by varying laser detuning and interaction radius. This work stretched one-dimensional demonstrations to two spatial dimensions, when theoretical and numerical techniques near saturation.

Google Quantum AI Lab (Digital Quantum Simulation) utilised the Sycamore processor.

The chip's superconducting loop states encoded the 2D quantum field, unlike the analogue method.

This “digital” quantum simulator delicately controls the quantum field's evolution “by hand” using discrete manipulations.

Frank Pollmann, a physicist from the Technical University of Munich (TUM) in Garching, Germany, who led the Google experiment, said both teams placed strings in the field that “effectively acted like rubber bands connecting two particles.” Researchers adjusted settings to make strings stiff, wobbly, or breakable. Pollmann sometimes said, “The whole string just dissolves: the particles become deconfined.”

Importance and Future

These experiments are necessary to employ quantum computers for simulations beyond regular machines. The results demonstrate the scalability of neutral-atom platforms like Aquila for simulating complex quantum field theories and set a benchmark for quantum simulation by pushing classical computational capabilities in real-time gauge-theory dynamics. This confirms the growing importance of quantum hardware for scientific study.

Simulating strings in a 2D electric field can be useful in material physics, but high-energy interactions like those in particle colliders, which require the stronger nuclear force, are difficult to replicate. Monika Aidelsburger, a physicist at Munich's Max Planck Institute of Quantum Optics, says these more complex simulations have “no clear path at this point how to get there”.

She added that quantum simulation has advanced “really amazing and very fast” overall. Because ‘qudits’ quantum systems with more than two quantum states may produce more accurate representations of a quantum field and enhance simulation power, researchers are considering using them. Christian Bauer and LBNL colleague Anthony Ciavarella were among the first to model the strong nuclear force with a quantum computer last year.

This research will boost particle physics and demonstrate quantum computing's scientific discovery potential.

Financial Support and Recognition

US National Science Foundation, Department of Energy, EU Quantum Flagship programme, Austrian Science Fund (FWF), and business partners funded the research. Aquila hardware time from QuEra Computing.

Quantum-classical mechanics as an alternative to quantum mechanics in molecular and chemical physics

In quantum mechanics, the theory of quantum transitions is grounded on the convergence of a series of time-dependent perturbation theory. In nuclear and atomic physics, this series converges because the dynamics of quantum transitions (quantum jumps) are absent by definition.

Global Particle Physics Excellence Awards

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Quantum Computing Software Market Comprehensive Study Explore Huge Growth

According to Market Statistix, the Quantum Computing Software Market revenue and growth prospects are expected to grow at a significant rate during the analysis period of 2024-2032, with 2023 as the base year. Quantum Computing Software Market research is an ongoing process. Regularly monitor and evaluate market dynamics to stay informed and adapt your strategies accordingly. As a market research and consulting firm, we offer market research reports that focus on major parameters, including Target Market Identification, Customer Needs and Preferences, Thorough Competitor Analysis, Market Size and market Analysis, and other major factors. In the end, we provide meaningful insights and actionable recommendations that inform decision-making and strategy development.

The Quantum Computing Software Market is projected to experience steady growth, expanding at a CAGR of 30.6% over the forecast period.

Who are the key players operating in the industry?

Riverlane, Google LLC, Zapata Computing, D-Wave Systems, Huawei Technology Co. Ltd., QC Ware, Rigetti Computing, Honeywell Inc., AWS Inc., Fujitsu Ltd., 1QBIT, IBM Corporation, Cambridge Quantum Computing, Accenture PLC, Microsoft Corporation

Request a sample on this latest research report Quantum Computing Software Market spread across 100+ pages and supported with tables and figures is now available @ https://www.marketstatistix.com/sample-report/global-quantum-computing-software-market

Quantum Computing Software Market Overview and Insights:

Market Statistix is solidifying its reputation as a leading market research and consulting service provider, delivering data-driven insights that help businesses make informed strategic decisions. By focusing on detailed demand analysis, accurate market forecasts, and competitive evaluations, we equip companies with the essential tools to succeed in an increasingly competitive landscape. This comprehensive Quantum Computing Software market analysis offers a detailed overview of the current environment and forecasts growth trends through 2032. Our expertise enables clients to stay ahead of the curve, providing actionable insights and competitive intelligence tailored to their industries.

What is included in Quantum Computing Software market segmentation?

The report has segmented the market into the following categories:

Segment by Type: Type I, Type II, Type III

Segment by Application: Optimization, Machine Learning, Simulation, Others

Quantum Computing Software market is segmented by company, region (country), by Type, and by Application. Players, stakeholders, and other participants in the Quantum Computing Software market will be able to gain the upper hand as they use the report as a powerful resource. The segmental analysis focuses on revenue and forecast by Type and by Application in terms of revenue and forecast for the period 2019-2032.

Have a query? Market an enquiry before purchase @ https://www.marketstatistix.com/enquiry-before-buy/global-quantum-computing-software-market

Competitive Analysis of the market in the report identifies various key manufacturers of the market. We do company profiling for major key players. The research report includes Competitive Positioning, Investment Analysis, BCG Matrix, Heat Map Analysis, and Mergers & Acquisitions. It helps the reader understand the strategies and collaborations that players are targeting to combat competition in the market. The comprehensive report offers a significant microscopic look at the market. The reader can identify the footprints of the manufacturers by knowing about the product portfolio, the global price of manufacturers, and production by producers during the forecast period.

As market research and consulting firm we offer market research report which is focusing on major parameters including Target Market Identification, Customer Needs and Preferences, Thorough Competitor Analysis, Market Size & Market Analysis, and other major factors.

Purchase the latest edition of the Quantum Computing Software market report now @ https://www.marketstatistix.com/buy-now?format=1&report=61

The Quantum Computing Software market research study ensures the highest level of accuracy and reliability as we precisely examine the overall industry, covering all the market fundamentals. By leveraging a wide range of primary and secondary sources, we establish a strong foundation for our findings. Industry-standard tools like Porter's Five Forces Analysis, SWOT Analysis, and Price Trend Analysis further enhance the comprehensiveness of our evaluation.

A Comprehensive analysis of consumption, revenue, market share, and growth rate is provided for the following regions:

-The Middle East and Africa region, including countries such as South Africa, Saudi Arabia, UAE, Israel, Egypt, and others.

-North America, comprising the United States, Mexico, and Canada.

-South America, including countries such as Brazil, Venezuela, Argentina, Ecuador, Peru, Colombia, and others.

-Europe (including Turkey, Spain, the Netherlands, Denmark, Belgium, Switzerland, Germany, Russia, the UK, Italy, France, and others)

-The Asia-Pacific region includes Taiwan, Hong Kong, Singapore, Vietnam, China, Malaysia, Japan, the Philippines, South Korea, Thailand, India, Indonesia, and Australia.

Browse Executive Summary and Complete Table of Content @ https://www.marketstatistix.com/report/global-quantum-computing-software-market

Table of Contents for the Quantum Computing Software Market includes the following points:

Chapter 01 - Quantum Computing Software Executive Summary

Chapter 02 - Market Overview

Chapter 03 - Key Success Factors

Chapter 04 - Quantum Computing Software Market – Pricing Analysis Overview

Chapter 05 - Overview of the History of the Quantum Computing Software Market

Chapter 06 - Quantum Computing Software Market Segmentation [e.g. Type (Type I, Type II, Type III), Application (Optimization, Machine Learning, Simulation, Others)]

Chapter 07 - Analysis of Key and Emerging Countries in the Quantum Computing Software

Chapter 08 - Quantum Computing Software Market Structure and Value Analysis

Chapter 09 - Competitive Landscape and Key Challenges in the Quantum Computing Software Market

Chapter 10 - Assumptions and Abbreviations

Chapter 11 - Market Research Approach for Quantum Computing Software

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Unleashing the Power of Quantum Computing:Description

Quantum computing represents a paradigm shift in computational capabilities, harnessing the principles of quantum mechanics to perform calculations that were once thought impossible. This transformative technology has the potential to revolutionize fields ranging from cryptography and optimization to drug discovery and materials science. for more info https://delibugle.in/benefits-of-quantum-computing-innovations/

Quantum Chemistry

Quantum chemistry is a subfield of chemistry focused on the application of quantum mechanics to chemical systems. It investigates the electronic structure, molecular dynamics, and reaction mechanisms of atoms and molecules using principles like Schrödinger’s equation, wavefunctions, and molecular orbitals. This field plays a critical role in predicting molecular behavior, designing new materials, and understanding fundamental chemical processes at the quantum level.

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Quantum Optical Circuits Market to Soar 🚀 $5.8B by 2034! 🔬 #QuantumTech #Innovation

Integrated Quantum Optical Circuits is revolutionizing data processing and secure communications through quantum mechanics. This market is characterized by advancements in quantum computing, telecommunications, and ultra-sensitive sensors, leveraging components like waveguides, modulators, and detectors. These innovations are driving next-generation high-performance and secure data solutions across industries.

To Request Sample Report : https://www.globalinsightservices.com/request-sample/?id=GIS23712 &utm_source=SnehaPatil&utm_medium=Article

Rapid growth in quantum computing and telecommunications is fueling market expansion. The quantum computing sector leads, backed by increasing R&D investments. Telecommunications follows, benefiting from the rising demand for high-speed data transmission. North America dominates, driven by strong technological infrastructure and substantial funding in quantum technologies. Europe ranks second, supported by collaborative initiatives and government-backed projects. The United States and Germany are the top-performing countries, leveraging innovative ecosystems and academic excellence. Meanwhile, the Asia-Pacific region, led by China and Japan, is witnessing rapid growth through strategic partnerships and increasing investments. This expansion is further bolstered by government support and a growing talent pool, ensuring continued breakthroughs in quantum technology.

Key market segments include active, passive, and hybrid components, catering to applications such as telecommunications, data centers, quantum computing, and biomedical research. The market also encompasses technologies like silicon photonics and lithium niobate, which are critical for fabricating advanced quantum optical circuits.

In 2024, the market achieved robust growth, reaching a volume of approximately 650 million units. The telecommunications sector leads with a 45% market share, driven by high-speed data demands. The healthcare sector holds 30%, leveraging quantum optics for advanced imaging, while the defense and aerospace sector captures 25%, utilizing quantum circuits for secure communications. This segmentation underscores the increasing reliance on quantum technologies across industries.

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Quantum-centric supercomputing for materials science represents a transformative approach to computational research, aiming to leverage the power of quantum computing to solve complex problems in material design and discovery. Contact For Enquiries: [email protected] Get Connected Here ---------------------- ---------------------- Instagram: www.instagram.com/amophysicsawards/ Facebook: www.facebook.com/profile.php?id=100092029748922 twitter: twitter.com/home pinterest: in.pinterest.com/physicsresearch2000/ blogger: www.blogger.com/u/5/blog/posts/4758468583908890312?pli=1 #QuantumComputing #Supercomputing #MaterialsScience #QuantumMaterials #QuantumTechnology #ComputationalScience #QuantumSimulations #QuantumAlgorithms #HighPerformanceComputing #QuantumFuture #MaterialDesign #QuantumPhysics #QuantumResearch #QuantumCentric #ScientificComputing #QuantumModeling #QuantumChallenges #NextGenComputing #QuantumInnovation #MaterialsResearch #QuantumEngineering #QuantumAdvancements #SupercomputerTech #QuantumMechanics #QuantumPotential #EmergingTechnologies #QuantumSimulations #QuantumTheory #QuantumRevolution #MaterialsInnovation

https://bit.ly/42z4h0J - 🔬 Quantum information (QI) processing, with its potential to revolutionize technology through unprecedented computational capabilities, security, and detection sensitivities, relies on the development of stable and efficient qubits. Researchers are exploring various platforms like superconducting Josephson junctions, trapped ions, topological qubits, ultra-cold neutral atoms, and diamond vacancies to find the best fit. #QuantumComputing #Qubits 🌡️ Nano-mechanical resonators are a promising potential platform for qubits. These oscillators, similar to springs or strings, produce varying sounds depending on the drive's strength. When cooled to absolute zero, their energy levels become quantized and continue to vibrate due to the Heisenberg uncertainty principle, thereby making the realization of a mechanical qubit possible. #NanomechanicalResonators #QuantumMechanics 🎯 The main challenge is to maintain significant non-linear effects in the quantum regime. A solid theoretical concept of a mechanical qubit, based on a nanotube resonator coupled to a double-quantum dot, was established in 2021 by Fabio Pistolesi, Andrew N. Cleland, and Adrian Bachtold. This demonstrated nanomechanical resonators as viable qubit candidates due to their potential for long coherence times. #QuantumPhysics #QubitResearch 💡 In a recent study published in Nature Physics, researchers took the first pre-experimental steps toward realizing a mechanical qubit. They demonstrated a new mechanism to boost the anharmonicity of a mechanical oscillator in its quantum regime by fabricating a suspended nanotube device and adjusting the voltage to allow the flow of only one electron onto the nanotube at a time. #QuantumExperiment #NaturePhysics ❄️ At nearly absolute zero temperatures, they observed non-linear vibrations in the nanotube, an astonishing feat given that other resonators showed non-linearities at amplitudes much greater than its zero-point motion. The anharmonicity increased as vibrations cooled closer to the ground state, contrary to previous observations in other mechanical resonators. #QuantumRegime #Nanotube 🚀 These results provide a stepping stone toward the development of mechanical qubits and quantum simulators. Future experiments that target cat states and mechanical qubits may benefit from coupling nanotube vibrations to a double-quantum dot, which could lead to stronger nonlinearities along with longer-lived mechanical states.

Clouds of ultracold atoms (just a fraction of a degree above absolute zero!) hover inside a vacuum chamber only held by electric and magnetic fields while fluorescing light. Find out how these atoms can be turned into a quantum simulator in @bea4keys post on @manybodyphysics.com (link in Bio). Photo by Apoorva Hedge . . . #photography #atoms #physics #cold #ultracold #ultracoldatoms #light #science @asapscience #Heidelberg #sciencecommunication #circles #geometry #structures #quantum #quantumcomputing #quantumsimulation (at Kirchhoff Institut Für Physik) https://www.instagram.com/p/BurlCsYl2co/?utm_source=ig_tumblr_share&igshid=7zlyaoat9vwf

Quantum Computing 2019 Update

New Post has been published on https://computercoolingstore.com/quantum-computing-2019-update/

Quantum Computing 2019 Update

Quantum computing review, including key concepts, recent developments from IBM, Intel, Google, Microsoft, D-Wave, Rigetti and other pioneers, and a discussion of the likely first commercial application of quantum molecular simulation.

You can download a pdf sampler “Digital Genesis” book from this page:

And my ExplainingTheFuture “Cyborg Fusion” video is here:

The MolView molecular modelling data visualization platform can be found here: (not quantum, but cool!).

REFERENCES & FURTHER INFORMATION I maintain an updated article on quantum computing, including information on all major pioneers and a great many links, at:

Articles and news releases specifically referred to in this video (in the order they are cited) are as follows:

IBM Q System One press release:

Intel quantum computing pages:

Google AI Quantum pages:

A New Law to Describe Quantum Computing’s Rise (Nevan’s Law):

Microsoft Quantum Network press release:

Microsoft open sources Quantum Development Kit:

D-Wave Systems launches Leap cloud-based quantum application environment:

Alibaba & CAS launch quantum computing cloud services:

Introducing Rigetti Quantum Cloud Services:

Quantum Circuits website:

IonQ website:

IBM reports of molecular modelling with its quantum computers: As reported in Nature:

World’s first quantum simulation of molecular bonds: — refers to this Physical Review X paper:

HQS Quantum Simulations website:

See ExplainingComputers for more:

#QuantumComputing #QuantumSimulation #ExplainingComputers

Quantum Computing 2019 Update

New Post has been published on https://computercoolingstore.com/quantum-computing-2019-update/

Quantum Computing 2019 Update

Quantum computing review, including key concepts, recent developments from IBM, Intel, Google, Microsoft, D-Wave, Rigetti and other pioneers, and a discussion of the likely first commercial application of quantum molecular simulation.

You can download a pdf sampler “Digital Genesis” book from this page:

And my ExplainingTheFuture “Cyborg Fusion” video is here:

The MolView molecular modelling data visualization platform can be found here: (not quantum, but cool!).

REFERENCES & FURTHER INFORMATION I maintain an updated article on quantum computing, including information on all major pioneers and a great many links, at:

Articles and news releases specifically referred to in this video (in the order they are cited) are as follows:

IBM Q System One press release:

Intel quantum computing pages:

Google AI Quantum pages:

A New Law to Describe Quantum Computing’s Rise (Nevan’s Law):

Microsoft Quantum Network press release:

Microsoft open sources Quantum Development Kit:

D-Wave Systems launches Leap cloud-based quantum application environment:

Alibaba & CAS launch quantum computing cloud services:

Introducing Rigetti Quantum Cloud Services:

Quantum Circuits website:

IonQ website:

IBM reports of molecular modelling with its quantum computers: As reported in Nature:

World’s first quantum simulation of molecular bonds: — refers to this Physical Review X paper:

HQS Quantum Simulations website:

See ExplainingComputers for more:

#QuantumComputing #QuantumSimulation #ExplainingComputers

Double Microwave Shielding Could Change Quantum Simulation

Researchers have developed "double microwave shielding," which could govern extremely cold polar molecules and lead to groundbreaking quantum information and simulation advances. According to recent investigations, this approach enabled the first Bose-Einstein condensate of polar molecules, a huge physics accomplishment.

Modern physics has strived to use ultracold molecules in quantum technology. Unlike atoms, molecules have strong, long-range dipole-dipole interactions, making them ideal for researching quantum ferrofluids and supersolids and producing tunable quantum matter. However, global collisional loss, an inbuilt instability, has impeded attempts to cool molecules to quantum degeneracy. Early attempts to avoid this developed degenerate Fermi gases by direct assembly, but inelastic losses persisted.

A major answer was collisional shielding, which engineers repulsive long-range interactions to minimise damaging short-range molecular encounters. Resonant static electric fields, repulsive dipolar interactions in quasi-two-dimensional gases, and microwave treatment with a single circularly polarised (+) field were used to achieve this. This “single microwave shielding” method efficiently suppresses two-body losses by establishing a spinning dipole moment that generates a time-averaged repulsive dipolar interaction via field-dressing molecules.

Single microwave shielding reduced two-body losses, but a strong dressing could cause loss by dipolar three-body recombination into a bound state, as with NaCs molecules. Due to an inherent trade-off between preventing two-body loss and mistakenly boosting three-body recombination, the approach was less effective.

Dual microwave control is innovative.

To overcome this basic difficulty, the novel 'double microwave shielding' technology combines two microwave fields with different frequencies and polarisations, usually a linearly polarised () field and a circularly polarised (+) field Dual-field technology allows unprecedented control. These fields cause molecular dipoles to rotate and oscillate, causing repulsive shielding interactions that prevent two-body collisional loss.

Importantly, the two microwave fields control dipolar interaction between molecules outside this repulsive barrier. The researchers found that the moments created by the two perpendicular fields can balance each other. The elimination of bound states that hindered single-field shielding and three-body recombination depend on this compensation. Bose-Einstein condensates, ultracold molecular vapours, are stable when the dipolar interaction is compensated, making the potential repulsive.

New Loss: Floquet Inelastic Collisions

Double microwave shielding works well, but it produces a new loss channel dubbed “Floquet inelastic” or photon number-changing collisions. In contrast to single-field shielding's short-range interactions, these collisions release energy on the order of the microwave beat frequency by exchanging photons between the dressing fields. This process is unique to multi-frequency dressing and the main residual loss mechanism for double microwave shielding. Even with this extra loss channel, losses are still substantially smaller than with single-field microwave shielding.

Complete Molecular Interaction Control

Beyond loss suppression, double microwave shielding offers unsurpassed molecular interaction management. Researchers can now fully change dipolar and scattering length sign and relative magnitude without compromising shielding. While the dipolar length measures long-range dipole-dipole interactions, the scattering length measures contact interactions and can range from massive positive values to zero to negative values.

This level of control is crucial for quantum many-body physics. The ratio of dipolar and contact interactions (ϵdd), a key parameter in dipolar quantum gas properties, can now be precisely controlled. Studies can go from weakly dipolar gases (where ϵdd is near to zero) to strongly dipolar gases (where ϵdd is greater than one) with positive or repulsive dipolar interactions.

The approach is universal for polar molecules like RbCs, NaK, NaRb, and KAg with varying dipole moments and weights. Studies show that shielding improves with dipole moment and mass. More importantly, when microwave parameters are scaled correctly, the “jagged” structure of collision rates and resonance locations shows a pattern across molecules.

Complete control over ultracold polar molecule interactions is a major advance. Double microwave shielding is a powerful method for controlling contact intensity, direction, and anisotropy while reducing two- and three-body loss. This discovery allows the study of many-body physics with strongly interacting dipolar quantum matter, which could lead to novel supersolid states of matter, quantum simulation of extended Hubbard models, and polar molecule-based quantum information platforms.

Quantum Computing 2019 Update

New Post has been published on https://computercoolingstore.com/quantum-computing-2019-update/

Quantum Computing 2019 Update

Quantum computing review, including key concepts, recent developments from IBM, Intel, Google, Microsoft, D-Wave, Rigetti and other pioneers, and a discussion of the likely first commercial application of quantum molecular simulation.

You can download a pdf sampler “Digital Genesis” book from this page:

And my ExplainingTheFuture “Cyborg Fusion” video is here:

The MolView molecular modelling data visualization platform can be found here: (not quantum, but cool!).

REFERENCES & FURTHER INFORMATION I maintain an updated article on quantum computing, including information on all major pioneers and a great many links, at:

Articles and news releases specifically referred to in this video (in the order they are cited) are as follows:

IBM Q System One press release:

Intel quantum computing pages:

Google AI Quantum pages:

A New Law to Describe Quantum Computing’s Rise (Nevan’s Law):

Microsoft Quantum Network press release:

Microsoft open sources Quantum Development Kit:

D-Wave Systems launches Leap cloud-based quantum application environment:

Alibaba & CAS launch quantum computing cloud services:

Introducing Rigetti Quantum Cloud Services:

Quantum Circuits website:

IonQ website:

IBM reports of molecular modelling with its quantum computers: As reported in Nature:

World’s first quantum simulation of molecular bonds: — refers to this Physical Review X paper:

HQS Quantum Simulations website:

See ExplainingComputers for more:

#QuantumComputing #QuantumSimulation #ExplainingComputers

Quantum Computing 2019 Update

New Post has been published on https://computercoolingstore.com/quantum-computing-2019-update/

Quantum Computing 2019 Update

Quantum computing review, including key concepts, recent developments from IBM, Intel, Google, Microsoft, D-Wave, Rigetti and other pioneers, and a discussion of the likely first commercial application of quantum molecular simulation.

You can download a pdf sampler “Digital Genesis” book from this page:

And my ExplainingTheFuture “Cyborg Fusion” video is here:

The MolView molecular modelling data visualization platform can be found here: (not quantum, but cool!).

REFERENCES & FURTHER INFORMATION I maintain an updated article on quantum computing, including information on all major pioneers and a great many links, at:

Articles and news releases specifically referred to in this video (in the order they are cited) are as follows:

IBM Q System One press release:

Intel quantum computing pages:

Google AI Quantum pages:

A New Law to Describe Quantum Computing’s Rise (Nevan’s Law):

Microsoft Quantum Network press release:

Microsoft open sources Quantum Development Kit:

D-Wave Systems launches Leap cloud-based quantum application environment:

Alibaba & CAS launch quantum computing cloud services:

Introducing Rigetti Quantum Cloud Services:

Quantum Circuits website:

IonQ website:

IBM reports of molecular modelling with its quantum computers: As reported in Nature:

World’s first quantum simulation of molecular bonds: — refers to this Physical Review X paper:

HQS Quantum Simulations website:

See ExplainingComputers for more:

#QuantumComputing #QuantumSimulation #ExplainingComputers

Quantum Computing 2019 Update

New Post has been published on https://computercoolingstore.com/quantum-computing-2019-update/

Quantum Computing 2019 Update

Quantum computing review, including key concepts, recent developments from IBM, Intel, Google, Microsoft, D-Wave, Rigetti and other pioneers, and a discussion of the likely first commercial application of quantum molecular simulation.

You can download a pdf sampler “Digital Genesis” book from this page:

And my ExplainingTheFuture “Cyborg Fusion” video is here:

The MolView molecular modelling data visualization platform can be found here: (not quantum, but cool!).

REFERENCES & FURTHER INFORMATION I maintain an updated article on quantum computing, including information on all major pioneers and a great many links, at:

Articles and news releases specifically referred to in this video (in the order they are cited) are as follows:

IBM Q System One press release:

Intel quantum computing pages:

Google AI Quantum pages:

A New Law to Describe Quantum Computing’s Rise (Nevan’s Law):

Microsoft Quantum Network press release:

Microsoft open sources Quantum Development Kit:

D-Wave Systems launches Leap cloud-based quantum application environment:

Alibaba & CAS launch quantum computing cloud services:

Introducing Rigetti Quantum Cloud Services:

Quantum Circuits website:

IonQ website:

IBM reports of molecular modelling with its quantum computers: As reported in Nature:

World’s first quantum simulation of molecular bonds: — refers to this Physical Review X paper:

HQS Quantum Simulations website:

See ExplainingComputers for more:

#QuantumComputing #QuantumSimulation #ExplainingComputers

Beautiful summary of Things a Quantum Computer can be used to make and optimum utilization of the technology... :)